DE3443497C2 - Color picture tube and display device with such a color picture tube - Google Patents

Description

The invention relates to a color picture tube with a piston, which consists of a neck, a cone and a flat or slightly convex picture window, which over a strongly curved part merges into a raised edge which is essentially parallel to the piston axis, the inner surface of the picture window via a the first, strongly curved surface with the radius of curvature r merges into the inner surface of this raised edge and the outer surface of the picture window via a second, strongly curved surface into the outer surface of this raised edge and in the vicinity of this transition the raised edge has a thickness d, which picture window is provided on the inside with an almost rectangular screen which contains a material which is at least one color luminescent, in front of which screen color selection means are positioned with the aid of hanging means attached in the corners of the upstanding edge, and in which neck means for ores At least one electron beam is attached, the distance D between the boundary ( 10 ) of the phosphor of the screen and the outer surface of the upstanding edge of the picture window being almost the same over the entire circumference of the window in a plane perpendicular to the tube axis. Such a color picture tube is known from DE-A1-32 15 742.

The invention has for its object to a picture display tube create a narrow and even dark edge strip around has the almost rectangular screen.

This task is accomplished with a color picture tube of the type mentioned at the beginning solved according to the invention in that a value r 10 for the radius of curvature mm is chosen and that the distance D, the thickness d and the radius of curvature Meet condition (D-d) / r 1.  

Through the use of the invention rectangular screen around just a narrow, almost at all areas have the same dark margin, the emphasizes the squareness of the screen. Also leads this narrow, almost equally wide, dark border on one tube in operation to one for the viewer advantageous image display. Because this edge does not lead to a noticeable distortion, for example one Number of even digits displayed on the screen columns. If the tube is not in use leads the narrow, almost everywhere in the same width Edge around the screen to an aesthetic shape. Also have trials and comparative calculations shown that an image window with an almost rectangular Outline both static and dynamic Load compared to the known tube, which is almost a has a flat picture window and a barrel-shaped outline, does not lose implosion protection.

According to the invention, the larger space is used, which is in the four corners of the picture window between the upstanding edge of the image window and the upright Edge of the color selection means. With an almost rectangular inner contour of the picture window and an almost rectangular outline of the raised edge of the color elective means the gain in space is at least one Factor √ with respect to the middle of the sides of the ge called rectangles. By using the invention this space gain can be exhausted in this sense that the limitation of the fluorescent of the screen in the opposite Set to the well-known picture tube along the inside contour of the image window can run. So an opti get the size of the screen on the picture window. This is between tubes with black matrix material importantly the phosphor elements of the screen, whereby this matrix material is outside the limit  the phosphor of the screen extends. However is this is also important for tubes without this matrix material, an aluminum film (metal backing) over the phosphor is attached, which is outside the limit of the Fluorescent stretches. Because in the first case without Use of the invention a broad, uneven, dark border formed, and in the second case a shiny, uneven edge (aluminum) from one of the high standing edge of the picture window caused dark edge is surrounded.  

Embodiments of the invention are described below with reference to the drawing explained in more detail. Show it:

Fig. 1 is a front view of a picture display tube according to the invention.

FIG. 2 shows a cross section through part of the edge and through the upstanding edge of the picture window of the picture display tube according to FIG. 1.

Fig. 3 is a rear view of an image window according to the invention, in which a shadow mask is suspended in the corners of the image window and

Fig. 4 is a perspective view of a possible suspension structure in a corner of the picture window.

In Fig. 1 is a front view of a picture tube is shown in which the contour of the image window 8 extends 9 almost parallel to the boundary 10 of the phosphor of the screen. 11 As a result, a dark edge 12 which is uniform in width is obtained around the almost rectangular screen 11 .

The values of a (distance of the boundary 10 of the phosphor of the screen 11 from the outline 8 of the image window 9 in the diagonal direction), b (distance in the middle of the long side) and c (distance in the center of the short side) are 19, 5, 20.9 and 20.0 mm, respectively. In the tube according to the invention, the width fluctuation of the dark edge is less than 1.5 mm, which is almost imperceptible. In a known tube, this fluctuation is a good 8 mm, which has a noticeably disturbing effect. The sides of the outline 8 have a radius of curvature of approximately 6.5 m.

FIG. 2 shows a cross section through part of the edge and through the upstanding edge 63 of the picture window 9 of the picture tube according to FIG. 1. The inner surface 64 of the image window 9 passes over a strongly curved upper surface 65 with a radius of curvature r into the inner surface 66 of the raised edge 63 . The radius of curvature r of the strongly curved surface 65 is between 3 and 10 mm and is approximately 8 mm here. The distance between the limit 10 loading of the phosphor of the screen 11 and the outer surface of the upstanding edge 63 is denoted by D and is 20.0 mm here, while the thickness of the upstanding edge 63 indicated by d is about 14.5 mm. The usual thin aluminum film, not shown here, is evaporated on the phosphor of the screen 11 . Due to the small radius of curvature of the strongly curved surface 65 and the passage of the phosphor of the screen 11 , the aluminum film is only visible in the form of a very narrow edge from the front of the tube. In the case of a matrix tube, the part of the aluminum film extending outside the boundary 10 is withdrawn from the eye of the beholder by black matrix material. From Fig. 1 it can be seen that in this case the dark edge 12 only widens to a very small extent.

By arranging the hanging means in the corners of the picture window, an optimal size of the screen on the picture window can be realized. Such a structure is shown schematically in FIG. 3, in which the image window 9 shown in FIG. 1 is shown in a rear view.

FIG. 4 shows a perspective view of a possible suspension structure with which the suspension structure shown schematically in FIG. 3 can be realized. In each corner of the upstanding edge 23 of the image window 9 , a metal pin 50 is melted. At the free end of the pin 50 there is a mandrel 51 which is provided with a conical cam 52 . The color selection means are formed by a thin, with a plurality of openings 42 perforated mask 40 , which is provided with a raised edge 21 . On the upstanding edge 41 , a diaphragm 39 is shown, partly in dashed lines, which prevents reflections of electrons at the upstanding edge 41 . In order to avoid differences in expansion between the mask 40 and the diaphragm 33 , both are made of the same material and have approximately the same thickness (150 μm). In the corner of the aperture 39 , a support strip 24 is fastened with two tongues 37 . A thin, flat, resilient element 25 is fastened to the tongues 37 via two narrow tongues 21 . The flat element 25 is provided with folded edges 26 which stiffen the element in the longitudinal direction. The flat element also runs almost perpendicular to the electron beam bent towards the corner in question. When the shadow mask 40 is thermally expanded, only the tongues 21 bend. The rest of the element 25 remains flat, so that the element 25 hinges almost around the end attached to the tongues 37 . A slot-shaped opening 27 is made in the flat spring element 25 near the end facing away from the support strip 24 . This opening 27 is partially covered by a plate 28 fastened on the element 25 with the opening 29 . The function of the plate 28 is explained in more detail below. In addition to the slot-shaped opening 27 in the flat spring element 25, there are two openings 30 and 31 through which the bent ends 32 and 33 of a wire spring 34, which is only partially visible in the figure, protrude. The other end 35 of the wire spring 34 is clamped to a bent tongue 36 which is fastened to the support strip 24 be. In this way, the wire spring 34 is stretched between the support strips 24 and fixed to the support strip facing away from the lower 24 end of the flat spring member 25th The wire spring 34 is also completely free of the flat spring element 25 . The support strip 24 is further provided with a stop which is not visible in the drawing and which limits the hinge movement in the direction of the arrowhead 60 of the flat spring element 25 .

The shadow mask 40 is hung in the picture window in that the spring elements 25 with the plates 28 with their openings 29 are arranged on the conical cams 52 of the pins 50 . The position of the shadow mask 40 with respect to the image window 9 is completely determined in this way by the flat spring elements 25 . The pin 50 runs almost perpendicular to the plane of the spring element 25 , which is pressed onto the pin 50 by the tensioned wire spring. The wire spring 34 ensures that the spring element 25 always assumes the same position on the cam 52 of the pin 50 after the occurrence of vibrations. The openings 30 and 31 , into which the bent ends 32 and 33 of the wire spring 34 are hooked, lie in line with the center of the opening 27 . The point of application of the tensile forces of the wire spring 34 thereby coincides with the axis of the cam 52 , so that the wire spring 34 can not exert a moment on the flat spring element 25 , as a result of which the position of the element 25 with respect to the cam 52 could change. The flat spring element 25 is attached to the shadow mask 40 at such an angle that it runs almost perpendicular to the electron beam deflected towards the corner of the image window 9 . When the shadow mask 40 is expanded, a small distance between the shadow mask 40 and the image window 9 is required to obtain a color-pure image.

Since the flat spring elements 25 are fastened to the shadow mask 40 in an almost hinged manner, they move in one direction on the image window during the expansion. The plate 28 serves to compensate for possible tolerances in the position of the pins 50 . Each plate 28 has two notches 38 through which the bent ends 32 and 33 of the wire spring 34 pass. The bent ends 32 and 33 of the wire spring 34 support the plate 28 so that the opening 29 with respect to the slot-shaped opening 27 in the flat spring element is held at an appropriate height and the plate 28 is displaceable with respect to the flat spring element 25 . After mounting on the cams 52 , the plates 27 are attached to the spring elements 25 . This has the effect that the position of the opening 29 corresponds exactly to the position of the conical cam 52 . If no loose plates 28 are used, 25 distortions of the shadow mask 40 can occur due to differences in the positions of the cams 52 and the openings 27 in the flat spring elements. After the mask ring 23 is suspended with the spring elements 25 in the image window 9 in the above manner, the mask 40 is inserted with the insertion of a distance gauge into the image window 9 , after which the aperture 23 is welded to the upstanding edge 41 of the shadow mask 40 . After the image window is provided with a suitable perforated mask in the manner described above, this image window is equipped in the usual way with a screen 11 .

This inner contour is formed by a line of points ge, at whose locations the inner surface 45 of the window 9 merges into a strongly curved surface 44 with a radius of curvature between 3 and 10 mm. The boundary 10 of the phosphor of the screen 11 coincides with this inner contour or almost together.

Claims (2)

1. Color picture tube with a piston, which consists of a neck, a cone and a flat or slightly convex image window ( 9 ), which merges over a strongly curved part into an upstanding edge ( 63 ) which is essentially parallel to the piston axis, the inner surface ( 64 ) of the image window ( 9 ) via a first, strongly curved surface ( 65 ) with the radius of curvature r into the inner surface ( 66 ) of this upstanding edge ( 63 ) and the outer surface of the image window ( 9 ) via a second, strongly curved surface in the outer surface of this upstanding edge ( 63 ) merges and in the vicinity of this transition the upstanding edge ( 63 ) has a thickness d, which image window ( 9 ) is provided on the inside with an almost rectangular screen ( 11 ) which is at least in one Color luminous fabric contains, in front of which screen ( 11 ) color selection means ( 40 ) with the help of in the corners of the upstanding edge ( 63 ) and the neck in which neck means for generating at least one electron beam are attached, the distance D between the boundary ( 10 ) of the phosphor of the screen ( 11 ) and the outer surface of the upstanding edge ( 63 ) in a plane perpendicular to the tube axis of the image window ( 9 ) is almost the same size over the entire circumference of the window, characterized in that a value r 10 mm is selected for the radius of curvature and that the distance D, the thickness d and the radius of curvature satisfy the condition (Dd) / r 1 fulfill. 2. Use of the color picture tube according to claim 1 in a display device.